The invention is made of a new kind of material called a metascreen, created from strips of copper tape attached to a flexible polycarbonate film. The copper strips are only 66 micrometers (66 millionths of a meter) thick, while the polycarbonate film is 100 micrometers thick, and the two are combined in a diagonal fishnet pattern.

The creation is a departure from previous attempts to create invisibility cloaks, which have aimed to bend light rays around an object so that they don't scatter, or reflect off it, a technique that relies on so-called bulk metamaterials. Instead, the new cloak uses a technique called mantle cloaking to cancel out light waves that bounce off the shielded object so that none survive to reach an observer's eye.

"When the scattered fields from the cloak and the object interfere, they cancel each other out and the overall effect is transparency and invisibility at all angles of observation," study co-author Andrea Alu, a physicist at the University of Texas at Austin, said in a statement.

In lab tests, Alu and his colleagues successfully hid a 7-inch-long (18 centimeters) cylindrical rod from view in microwave light. They said the same technology should be able to cloak oddly shaped and asymmetrical objects, too.

"The advantages of the mantle cloaking over existing techniques are its conformability, ease of manufacturing and improved bandwidth," Alu said. "We have shown that you don't need a bulk metamaterial to cancel the scattering from an object — a simple patterned surface that is conformal to the object may be sufficient and, in many regards, even better than a bulk metamaterial."

"In fact, metascreens are easier to realize at visible frequencies than bulk metamaterials and this concept could put us closer to a practical realization," Alu said. "However, the size of the objects that can be efficiently cloaked with this method scales with the wavelength of operation, so when applied to optical frequencies we may be able to efficiently stop the scattering of micrometer-sized objects."

The invention isn't just a novelty to thrill Harry Potter fans and aspiring spies. The researchers say it could have practical applications down the line, such as in noninvasive sensing devices or in biomedical instruments. They described their device in a paper published in the March 26 issue of the New Journal of Physics.